Optimization of WEDM process parameters for machining hybrid composites (LM6/B4C/Fly Ash) release_7fefwjmj2rh63boqsngemuemcu

Abstract

<jats:sec><jats:title>Introduction</jats:title>Wire-electric discharge machining (WEDM) possesses multiple benefits over traditional production approaches; it allows for the precise processing of complex and rigid particulate-reinforced composite materials. Aluminium alloys have found widespread applications in surgical components, shipbuilding, aircraft, automobiles, and inhaling gas cylinders for scuba diving, due to its good strength, and light weight properties.</jats:sec><jats:sec><jats:title>Methods</jats:title>The main aim of this investigation is to optimize different process variables for LM6/B<jats:sub>4</jats:sub>C/Fly ash particle reinforced hybrid composites using WEDM to attain performance metrics such as maximum material removal rate (MRR) and minimal surface roughness (SR). Taguchi's L<jats:sub>27</jats:sub> orthogonal array (OA) matrix and Grey Relational Analysis (GRA) were used.</jats:sec><jats:sec><jats:title>Results and Discussion</jats:title>According to ANOVA, the two variables with the most significant impact on MRR and SR are gap voltage and reinforcement percentage, with respective impacts of 29.59% and 20.69%. When the composite is machined, the following process variables work best: GV of 30 V, T<jats:sub>on</jats:sub> of 10 µs, T<jats:sub>off</jats:sub> of 2 µs, WF of 4 m/min, and R of 6%. A low gap voltage causes the erosion to rise and the MRR to increase. However, SR will also increase which is undesirable, so optimum gap voltage values are required for WEDM.</jats:sec>
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